Juice is a drink made from the extraction or pressing of the natural liquid contained in fruit and vegetables. It can also refer to liquids that are flavored with concentrate or other biological food sources, such as meat or seafood, such as clam juice. Juice is commonly consumed as a beverage or used as an ingredient or flavoring in foods or other beverages, as for smoothies. Juice emerged as a popular beverage choice after the development of pasteurization methods enabled its preservation without using fermentation (which is used in wine production).[1] The largest fruit juice consumers are New Zealand (nearly a cup, or 8 ounces, each day) and Colombia (more than three quarters of a cup each day). Fruit juice consumption on average increases with a country's income level.[2]

A glass of orange juice
A hand press juicer


Fruit juice being used in the preparation of a smoothie

The word "juice" comes from Old French in about 1300; it developed from the Old French words "jus, juis, jouis", which mean "liquid obtained by boiling herbs".[3] The "Old French jus "juice, sap, liquid" (13c.)...[came] from Latin ius [which means] "broth, sauce, juice, soup," from PIE root *yeue- "to blend, mix food" (cognates: Sanskrit yus- "broth," Greek zyme "a leaven", Old Church Slavonic jucha "broth, soup," Russian: уха "ukha", Lithuanian: juse "fish soup")."[3] The use of the word "juice" to mean "the watery part of fruits or vegetables" was first recorded in the early 14th century.[3] Since the 19th century, the term "juice" has also been used in a figurative sense (e.g., to mean alcohol or electricity). Today, "au jus" refers to meat served along with its own juice, commonly as a gravy.


Pomegranates getting washed prior to processing in an Afghanistan fruit concentrate factory.

Juice is prepared by mechanically squeezing or macerating (sometimes referred to as cold pressing[4]) fruit or vegetable flesh without the application of heat or solvents. For example, orange juice is the liquid extract of the fruit of the orange tree, and tomato juice is the liquid that results from pressing the fruit of the tomato plant. Juice may be prepared in the home from fresh fruit and vegetables using a variety of hand or electric juicers. Many commercial juices are filtered to remove fiber or pulp, but high-pulp fresh orange juice is a popular beverage. Additives are put in some juices, such as sugar and artificial flavours (in some fruit juice-based beverages) or savoury seasonings (e.g., in Clamato or Caesar tomato juice drinks). Common methods for preservation and processing of fruit juices include canning, pasteurization, concentrating,[5] freezing, evaporation and spray drying.

Although processing methods vary between juices, the general processing method of juices includes:[6]

  • Washing and sorting food source
  • Juice extraction
  • Straining, filtration and clarification
  • Blending pasteurization
  • Filling, sealing and sterilization
  • Cooling, labeling and packing

After the fruits are picked and washed, the juice is extracted by one of two automated methods. In the first method, two metal cups with sharp metal tubes on the bottom cup come together, removing the peel and forcing the flesh of the fruit through the metal tube. The juice of the fruit, then escapes through small holes in the tube. The peels can then be used further, and are washed to remove oils, which are reclaimed later for usage. The second method requires the fruits to be cut in half before being subjected to reamers, which extract the juice.

After the juice is filtered, it may be concentrated in evaporators, which reduce the size of juice by a factor of 5, making it easier to transport and increasing its expiration date. Juices are concentrated by heating under a vacuum to remove water, and then cooling to around 13 degrees Celsius. About two thirds of the water in a juice is removed.[6] The juice is later reconstituted, a process in which the concentrate is mixed with water and other factors to return any lost flavor from the concentrating process. Juices can also be sold in a concentrated state, in which the consumer adds water to the concentrated juice as preparation.

Juices are then pasteurized and filled into containers, often while still hot. If the juice is poured into a container while hot, it is cooled as quickly as possible. Packages that cannot stand heat require sterile conditions for filling. Chemicals such as hydrogen peroxide can be used to sterilize containers. Plants can make anywhere from 1 to 20 tonnes a day.[6]


A variety of packaged juices in a supermarket

High-intensity pulsed electric fields are being used as an alternative to heat pasteurization in fruit juices. Heat treatments sometimes fail to make a quality, microbiological stable product.[7] However, it was found that processing with high-intensity pulsed electric fields (PEF) can be applied to fruit juices to provide a shelf-stable and safe product.[7] In addition, it was found that pulsed electric fields provide a fresh-like product with high nutritional value.[7] Pulsed electric field processing is a type of nonthermal method for food preservation.[8]

Pulsed electric fields use short pulses of electricity to inactivate microbes. In addition, the use of PEF results in minimal detrimental effects on the quality of the food. PEFs kill microorganisms and provide better maintenance of the original colour, flavour, and nutritional value of the food as compared to heat treatments. This method of preservation works by placing two electrodes between liquid juices, then applying high-voltage pulses for microseconds to milliseconds. The high voltage pulses are of intensity in the range of 10 to 80 kV/cm.

Processing time of the juice is calculated by multiplying the number of pulses with the effective pulse duration. The high voltage of the pulses produce an electric field that results in inactivation of microbes that may be present in the juice. The PEF temperatures are below the temperatures used in thermal processing. After the high-voltage treatment, the juice is aseptically packaged and refrigerated. Juice is also able to transfer electricity due to the presence of several ions from the processing. When the electric field is applied to the juice, electric currents are then able to flow into the liquid juice and transferred around due to the charged molecules in the juice. Therefore, pulsed electric fields are able to inactivate microorganisms, extend shelf life, and reduce enzymatic activity of the juice while maintaining similar quality as the original, fresh pressed juice.


In the United Kingdom, the name or names of the fruit followed by juice can only legally be used to describe a product which is 100% fruit juice, as required by the Fruit Juices and Fruit Nectars (England) Regulations[9] and the Fruit Juices and Fruit Nectars (Scotland) Regulations 2003.[10] However, a juice made by reconstituting concentrate can be called juice. A product described as fruit "nectar" must contain at least 25% to 50% juice, depending on the fruit. A juice or nectar including concentrate must state that it does. The term "juice drink" is not defined in the Regulations and can be used to describe any drink which includes juice, whatever the amount.[11] Comparable rules apply in all EU member states in their respective languages.

In the US, fruit juice can only legally be used to describe a product which is 100% fruit juice. A blend of fruit juice(s) with other ingredients, such as high-fructose corn syrup, is called a juice cocktail or juice drink.[12] According to the Food and Drug Administration (FDA), the term "nectar" is generally accepted in the US and in international trade for a diluted juice to denote a beverage that contains fruit juice or puree, water, and artificial sweeteners.[13] "No added sugar" is commonly printed on labels of juice containers, but the products may contain large amounts of naturally occurring sugars;[14][15] however, sugar content is listed with other carbohydrates on labels in many countries.

Depending on trends and regulations, beverages listed as 100% juice may actually contain unlisted additives. For example, most orange juice contains added ethyl butyrate (to enhance flavor), vitamin C (as ascorbic acid), and water (if from concentrate). When fruit juice is too sour, acidic, or rich to consume, it may be diluted with water and sugar to create an -ade (such as lemonade, limeade, cherryade, and orangeade). The 'ade' suffix may also refer to any sweetened, fruit-flavored drink, whether or not it actually contains any juice.

Health effects

Advertisers often urge parents to buy juice for their children.

Juices are often consumed for their perceived health benefits. For example, orange juice with natural or added vitamin C, folic acid, and potassium.[16] Juice provides nutrients such as carotenoids, polyphenols and vitamin  C that offer health benefits.[17]

High consumption of fruit juice with added sugar may be linked to weight gain,[18][19] but not all studies have shown this effect.[20] If 100% from fruit, juice can help meet daily intake recommendations for some nutrients.[21]

100% fruit juice

Research suggests that 100% fruit juice is not associated with increased risk of diabetes.[22][23][24] A 2018 review concluded that 100% fruit juice increases the risk of tooth decay in children but there is "no conclusive evidence that consumption of 100% fruit juice has adverse health effects."[25]

Cranberry juice

Although preliminary research indicated that cranberry (juice or capsules) may decrease the number of urinary tract infections in women with frequent infections,[26] a more substantial Cochrane review concluded that there is insufficient evidence to indicate that cranberry juice consumption has any effect on urinary tract infections.[27] Long-term tolerance is also an issue[27] with gastrointestinal upset occurring in more than 30% of people.[28]

Negative effects

The American Academy of Pediatrics as of 2017 says that fruit juice should not be given to children under age one due to the lack of nutritional benefit.[29] For children ages one to six, intake of fruit juice should be limited to less than 4–6 oz (110–170 g) per day (about a half to three-quarters of a cup)[29] due to its high sugar and low fiber content compared to fruit. Overconsumption of fruit juices may reduce nutrient intake compared to eating whole fruits, and may produce diarrhea, gas, abdominal pain, bloating, or tooth decay.[30][31]

Overconsumption of fruits and fruit juice may contribute to dental decay and cavities via the effect of fruit acids on tooth enamel.[32] Longitudinal prospective cohort studies showed a significantly increased risk of type 2 diabetes when juices with added sugars were consumed compared to eating whole fruits.[33] A 2014 review found that higher intake of sugar-sweetened fruit juice was significantly associated with risk of type 2 diabetes.[22]

Overconsumption of fruit juice with added sugars has also been linked to childhood obesity. The American Journal of Public Health proposed that the Healthy Hunger-Free Kids Act of 2010 in the United States eliminate 100% fruit juices and substitute instead with whole fruits.[34]

Amount consumed

The largest fruit juice consumers are New Zealand (nearly a cup, or 8 ounces, each day) and Colombia (more than three quarters of a cup each day). Fruit juice consumption on average increased with country income level.[2]

In 2007, a report stated that fruit juice consumption overall in Europe, Australia, New Zealand and the US has increased in recent years.[35]

In 2015, people in the United States consumed approximately 6.6 US gallons of juices per capita with more than half of preschool-age children being regular drinkers.[36]

Juice bars

Juice bar selling fresh oranges, red apples and other fruits behind a display case, in Singapore.
A juice drinks serving Jungle Juice Bar at the Galleria Esplanad shopping mall in Helsinki, Finland

A juice bar is an establishment that primarily serves prepared juice beverages such as freshly squeezed or extracted fruit juices, juice blends, fruit smoothies (a thick fruit drink, often iced), or other juices such as fresh wheatgrass juice. Sometimes other solid ingredients or nutritional supplements may be added as boosters, such as fresh bananas, nuts or nut butter, bodybuilding supplements, soy protein powder or others such as whey or hemp protein powders, wheat germ, or spirulina or chlorella. Also if less juice is used with these same ingredients drinks called health shakes may be produced.

Juice bars share some of the characteristics of a coffeehouse, a soda fountain, a café, and a snack bar, such as providing blended drinks and food, such as sandwiches. Juice bars may be standalone businesses in cities or located at gyms, along commuter areas, near lunchtime areas, at beaches, and at tourist attractions. In Mexico, juice bars have become more popular in the 2000s. Mexican juice bars often also sell healthy beverages and snacks.


Groups of grape pits dated to 8000 BCE show early evidence of juice production; although it is thought that the grapes may have been alternatively used to produce wine. One of the first regularly produced juices was lemonade, appearing in 16th-century Italy, as an import, after its conception in the Middle East. Orange juice originated in the 17th century. In the 18th century, James Lind linked citrus fruits to the prevention of scurvy, which, a century later, led to the implementation of the Merchant Shipping Act of 1867, requiring all ocean-bound British ships to carry citrus-based juice on board.

In 1869, a dentist by the name of Thomas B. Welch developed a pasteurization method that allowed for the storage of juice, without the juice fermenting into alcohol. His method involved filtering squeezed grape juice into bottles, sealing them with cork and wax, and then placing them in boiling water. This method kills the yeast responsible for fermentation. He then sold his new product as "Dr Welch's Unfermented Wine".[37] In the late 18th-century United States, circulation of foreign fruit juices were heavily regulated by tariffs. The McKinley Tariff Act of 1890 increased import taxes from 38 to 49.5 percent, and set taxes on fruit juices based on the alcohol content of the drink. Juices with 18% or less alcohol were taxed 60 cents per gallon, while anything above 18% was taxed US$2.50 per proof gallon.[1]

Figurative uses

The use of the word "juice" to mean "liquor" (alcohol) is from 1828.[3] The use of the term "juice" to mean "electricity" dates from 1896.[3] As a verb, the word "juice" was first recorded as meaning "to enliven" in 1964.[3] The adjective "juiced" is recorded as meaning "drunk" in 1946 and in 2003 "enhanced or as if enhanced by steroids".[3] The adjective "juicy" has meant "succulent" since the 15th century (e.g., a juicy roast beef).[3] The figurative meaning "wealthy, full of some desired quality" dates from the 1620s[3] (e.g., a pirate calling a heavily laden ship he aims to plunder a "juicy catch"). The meaning "lively, suggestive, racy, sensational" (e.g., a juicy scandal) is from 1883.[3]

See also


  1. Ryan A. Ward (2011-05-01). "A Brief History of Fruit and Vegetable Juice Regulation in the United States" (PDF). Works.bepress.com. Retrieved 2015-12-27.
  2. Singh, Gitanjali M.; Micha, Renata; Khatibzadeh, Shahab; Shi, Peilin; Lim, Stephen; Andrews, Kathryn G.; Engell, Rebecca E.; Ezzati, Majid; Mozaffarian, Dariush; Müller, Michael (5 August 2015). "Global, Regional, and National Consumption of Sugar-Sweetened Beverages, Fruit Juices, and Milk: A Systematic Assessment of Beverage Intake in 187 Countries". PLOS ONE. 10 (8): e0124845. Bibcode:2015PLoSO..1024845S. doi:10.1371/journal.pone.0124845. PMC 4526649. PMID 26244332.
  3. "Online Etymology Dictionary". Retrieved 26 January 2017.
  4. "Juicer Types: The Difference Between Cold Press Juicers vs. Centrifugal Juice Extractors". Huffingtonpost.com. 2013-02-08. Retrieved 2014-08-25.
  5. "Understanding Concentrated Juice". Fitday.
  6. "Fruit Juice Processing, Fruit Juice Powder Plant, Fruit Juice Processing Plant, Juice Powder Plant". sspindia.com. Retrieved 7 May 2015.
  7. Toepfl, S.; Heinz, V.; Knorr, D. (June 2007). "High intensity pulsed electric fields applied for food preservation". Chemical Engineering and Processing: Process Intensification. 46 (6): 537–546. doi:10.1016/j.cep.2006.07.011.
  8. Advances in Food Process Engineering Research and Applications. Food Engineering Series. Springer. 2013. doi:10.1007/978-1-4614-7906-2. ISBN 978-1-4614-7905-5. S2CID 113436343.
  9. "Fruit Juices and Fruit Nectars (England) Regulations" (PDF). Retrieved 2014-08-25.
  10. https://www.food.gov.uk/multimedia/pdfs/draftssifruitjuice.pdf "Fruit Juices & Fruit Nectars (Scotland) Regulations 2003" (PDF). Archived from the original (PDF) on March 16, 2006. Retrieved 2014-08-25. {{cite web}}: Check |archive-url= value (help)
  11. https://www.health78.com/health-news/Parents-beware-juice-in-juice-drinks-costs-up-to-34-per-litre/5454/ "Parents beware: Juice in juice drinks costs up to £34 $10 per litre!". Health78.com. Archived from the original on 2014-10-09. Retrieved 2014-08-25. {{cite web}}: Check |archive-url= value (help)
  12. https://www.cfsan.fda.gov/~lrd/CF102-33.HTML "The Code of Federal Regulations, Title 21 Sec. 102.33 Beverages that contain fruit or vegetable juice". Archived from the original on December 3, 2008. Retrieved 2014-08-25. {{cite web}}: Check |archive-url= value (help)
  13. https://www.cfsan.fda.gov/~comm/juiceqa2.html "FDA Juice HACCP Regulation: Questions & Answers". 2003-09-04. Archived from the original on May 13, 2009. Retrieved 2014-08-25. {{cite web}}: Check |archive-url= value (help)
  14. "Canadian Food Inspection Agency: Criteria for the Nutrient Content Claim No Added Sugars". Inspection.gc.ca. Retrieved 2014-08-25.
  15. https://www.betterhealth.vic.gov.au/bhcv2/bhcarticles.nsf/pages/Child_nutrition_juices_and_sweet_drinks?open "Juice and sweet drinks - children". State Government of Victoria. Archived from the original on August 4, 2004. Retrieved 17 October 2014. {{cite web}}: Check |archive-url= value (help)
  16. Franke, AA; Cooney, RV; Henning, SM; Custer, LJ (2005). "Bioavailability and antioxidant effects of orange juice components in humans". J Agric Food Chem. 53 (13): 5170–8. doi:10.1021/jf050054y. PMC 2533031. PMID 15969493.
  17. Benton, David; Young, Hayley A (2019). "Role of fruit juice in achieving the 5-a-day recommendation for fruit and vegetable intake". Nutrition Reviews. 77 (11): 829–843. doi:10.1093/nutrit/nuz031. PMC 6786897. PMID 31504822.
  18. Myles S. Faith; Barbara A. Dennison; Lynn S. Edmunds; Howard H. Stratton (2006-07-27). "Fruit Juice Intake Predicts Increased Adiposity Gain in Children From Low-Income Families: Weight Status-by-Environment Interaction". Pediatrics. 118 (5): 2066–2075. doi:10.1542/peds.2006-1117. PMID 17079580. S2CID 25420639.
  19. Andrea M Sanigorski; A Colin Bell; Boyd A Swinburn (2006-07-04). "Association of key foods and beverages with obesity in Australian schoolchildren". Public Health Nutrition. 10 (2): 152–157. doi:10.1017/s1368980007246634. hdl:10536/DRO/DU:30007696. PMID 17261224.
  20. O'Neil, CE; Nicklas, TA; Kleinman, R (Mar 2010). "Relationship between 100% juice consumption and nutrient intake and weight of adolescents". Am J Health Promot. 24 (4): 231–7. doi:10.4278/ajhp.080603-quan-76. PMID 20232604. S2CID 25724565.
  21. "All About the Fruit Group". Choose MyPlate. 11 February 2015. Retrieved 28 May 2017.
  22. Xi, Bo; Li, Shuangshuang; Liu, Zhaolu; Tian, Huan; Yin, Xiuxiu; Huai, Pengcheng; Tang, Weihong; Zhou, Donghao; Steffen, Lyn M. (28 March 2014). "Intake of Fruit Juice and Incidence of Type 2 Diabetes: A Systematic Review and Meta-Analysis". PLOS ONE. 9 (3): e93471. Bibcode:2014PLoSO...993471X. doi:10.1371/journal.pone.0093471. PMC 3969361. PMID 24682091.
  23. Murphy, M.; Barrett, E.; Bresnahan, K.; Barraj, L. (2017). "100 % Fruit juice and measures of glucose control and insulin sensitivity: A systematic review and meta-analysis of randomised controlled trials". Journal of Nutritional Science. 6: E59. doi:10.1017/jns.2017.63. PMC 5736636. PMID 29299307.
  24. "100 Percent Fruit Juice Does Not Affect Blood Sugar Levels". Retrieved December 22, 2019.
  25. Auerbach, Brandon J; Dibey, Sepideh; Vallila-Buchman, Petra; Kratz, Mario; Krieger, James (2018). "Review of 100% Fruit Juice and Chronic Health Conditions: Implications for Sugar-Sweetened Beverage Policy". Advances in Nutrition. 9 (2): 78–85. doi:10.1093/advances/nmx006. PMC 5916434. PMID 29659683.
  26. Wang CH, Fang CC, Chen NC, Liu SS, Yu PH, Wu TY, Chen WT, Lee CC, Chen SC (July 9, 2012). "Cranberry-containing products for prevention of urinary tract infections in susceptible populations: a systematic review and meta-analysis of randomized controlled trials". Archives of Internal Medicine. 172 (13): 988–96. doi:10.1001/archinternmed.2012.3004. PMID 22777630.
  27. Jepson, Ruth G; Williams, Gabrielle; Craig, Jonathan C (17 October 2012). "Cranberries for preventing urinary tract infections". Cochrane Database of Systematic Reviews. 10: CD001321. doi:10.1002/14651858.CD001321.pub5. PMC 7027998. PMID 23076891.
  28. Rossi R, Porta S, Canovi B (September 2010). "Overview on cranberry and urinary tract infections in females". Journal of Clinical Gastroenterology. 44 Suppl 1: S61–2. doi:10.1097/MCG.0b013e3181d2dc8e. PMID 20495471.
  29. Heyman, Melvin B.; Abrams, Steven A. (22 May 2017). "Fruit Juice in Infants, Children, and Adolescents: Current Recommendations" (PDF). Pediatrics. 139 (6): e20170967. doi:10.1542/peds.2017-0967. PMID 28562300. S2CID 6024335.
  30. "Feeding Your Baby and Toddler (Birth to Age Two): Your Child: University of Michigan Health System". Med.umich.edu. Retrieved 2014-08-25.
  31. American Academy of Pediatrics Committee on Nutrition (May 2001). "The use and misuse of fruit juice in pediatrics". Pediatrics. 107 (5): 1210–3. doi:10.1542/peds.107.5.1210. PMID 11331711.
  32. "Delivering better oral health: an evidence-based toolkit for prevention" (PDF). Public Health England. June 2014. {{cite journal}}: Cite journal requires |journal= (help)
  33. Muraki, Isao; Imamura, Fumiaki; Manson, Joann E.; Hu, Frank B.; Willett, Walter C.; van Dam, Rob M.; Sun, Qi (29 August 2013). "Fruit consumption and risk of type 2 diabetes: results from three prospective longitudinal cohort studies". BMJ. 347 (aug28 1): f5001. doi:10.1136/bmj.f5001. PMC 3978819. PMID 23990623.
  34. Wojcicki, Janet M.; Heyman, Melvin B. (September 2012). "Reducing Childhood Obesity by Eliminating 100% Fruit Juice". American Journal of Public Health. 102 (9): 1630–1633. doi:10.2105/AJPH.2012.300719. PMC 3482038. PMID 22813423.
  35. https://www.the-infoshop.com/study/zi24456_weurope_fruit_juice_toc.html "[Report] West Europe Fruit Juice Market Research, Trends, Analysis TOC". Archived from the original on September 28, 2007. {{cite web}}: Check |archiveurl= value (help)
  36. Cheng, Erika R.; Fiechtner, Lauren G.; Carroll, Aaron E. (2018-07-07). "Seriously, Juice Is Not Healthy". The New York Times. Retrieved 2018-07-09.
  37. Morris, Justin R. (October 1998). "Factors Influencing Grape Juice Quality". HortTechnology. 8 (4): 471–478. doi:10.21273/HORTTECH.8.4.471.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.